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Accessing Diverse Pyridine-Based Macrocyclic Peptides by a Two-Site Recognition Pathway

Dinh Thanh Nguyen, Tung Le, Andrew J. Rice, Graham A. Hudson, Wilfred A. van der Donk, Douglas A. Mitchell

2022Journal of the American Chemical Society29 citationsDOIOpen Access PDF

Abstract

Macrocyclic peptides are sought-after molecular scaffolds for drug discovery, and new methods to access diverse libraries are of increasing interest. Here, we report the enzymatic synthesis of pyridine-based macrocyclic peptides (pyritides) from linear precursor peptides. Pyritides are a recently described class of ribosomally synthesized and post-translationally modified peptides (RiPPs) and are related to the long-known thiopeptide natural products. RiPP precursors typically contain an N-terminal leader region that is physically engaged by the biosynthetic proteins that catalyze modification of the C-terminal core region of the precursor peptide. We demonstrate that pyritide-forming enzymes recognize both the leader region and a C-terminal tripeptide motif, with each contributing to site-selective substrate modification. Substitutions in the core region were well-tolerated and facilitated the generation of a wide range of pyritide analogues, with variations in macrocycle sequence and size. A combination of the pyritide biosynthetic pathway with azole-forming enzymes was utilized to generate a thiazole-containing pyritide (historically known as a thiopeptide) with no similarity in sequence and macrocycle size to the naturally encoded pyritides. The broad substrate scope of the pyritide biosynthetic enzymes serves as a future platform for macrocyclic peptide lead discovery and optimization.

Topics & Concepts

ChemistryTripeptidePeptideStereochemistryCombinatorial chemistryEnzymeBiochemistryBiochemical and Structural CharacterizationMicrobial Natural Products and BiosynthesisChemical Synthesis and Analysis
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